JP2015109794A - Versatile cooling housing for electrical motor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To use the same stator parts for gas or liquid cooling.SOLUTION: An electrical device comprises a housing 20 having a plurality of cooling fins 24, and a laminated magnetic stack 16A. The plurality of cooling fins are located in a central portion along an exterior surface 20B of the housing, and the laminated magnetic stack is disposed within the central portion of the housing and interfacing with an interior surface 20A of the housing. The plurality of cooling fins are alternately higher and smaller on an inlet manifold and in opposition on an outlet manifold, and all the higher cooling fins have a same height for supporting a cover plate 26. The cover plate resting on the higher cooling fins has an inlet hole 26A receiving liquid cooling from the inlet manifold and an outlet hole 26B delivering the liquid cooling to the outlet manifold, and creates a liquid cooling path between higher and smaller cooling fins from the inlet hole to the outlet hole.

Description

  The present invention relates to the field of electric machines, and more particularly to a cooling housing for an electric motor that can be used regardless of gas cooling or liquid cooling.

  Classically, increasing the power of an electric motor (with the same effective length) leads to changing the cooling of the stator part from gas (especially air) cooling to liquid (especially water) cooling. This deployment requires significant changes in the stator portion, particularly in the liquid cooling inlet and outlet manifolds. Also, multiple additional seals are required to prevent leakage of internal liquid and change of the cooling circuit and increase the efficiency of liquid flow (eg, alternative countercurrent).

  Thus, so far, a complete redesign of the stator part is necessary to change the fluid used for cooling.

  The object of the present invention is to overcome these disadvantages of the prior art by using the same stator part for both gas cooling and liquid cooling.

  The present invention is a housing for an electrical device comprising an inner surface configured to be coupled to a laminated magnetic stack of the electrical device at a central portion, and an outer surface comprising a plurality of cooling fins at the central portion. The plurality of cooling fins are alternately higher and lower at the inlet manifold, and opposite at the outlet manifold, and all of the higher cooling fins are The cover plate has a same height for supporting the cover plate, the cover plate having an inlet hole for receiving liquid cooling from the inlet manifold and an outlet hole for delivering liquid cooling to the outlet manifold; Creates a liquid cooling passage between the higher and lower cooling fins from the inlet hole to the outlet hole In order rests high cooling fins than the, by the housing, to achieve these goals.

  With this versatile structure, the determination of the cooling type for each motor unit should be made at the very last stage of the manufacturing process (customer system assembly), and therefore it is improved logistics ( cause logistics and production costs.

  Preferably, the cover plate is fixed to the housing by a fixing means, and a seal is fitted between the cover plate and the housing to isolate liquid cooling, and the cooling fin is formed on the outer surface. It is realized by sand casting such that the surface roughness is compatible with heat exchange. Advantageously, all of the small cooling fins are the same height.

  The present invention is also an electric device having a housing having a plurality of cooling fins and a laminated magnetic stack, wherein the plurality of cooling fins are located at a central portion along the outer surface of the housing, Wherein the plurality of cooling fins alternate between higher and lower at the inlet manifold in an electrical device disposed within the housing and coupled to an inner surface of the housing at the central portion. It is the opposite for the outlet manifold, and all of the higher cooling fins are at the same height to support the cover plate, and the cover plate is liquid from the inlet manifold. An inlet hole for receiving cooling and an outlet hole for delivering liquid cooling to the outlet manifold, the cover plate being To produce a liquid cooling passage between the lower cooling fins and a higher cooling fins to the outlet hole from said inlet hole, rests on a higher cooling fins than the, related to the electrical device.

  The present invention will be better understood in view of the following detailed description with illustrations and non-limiting examples with reference to the accompanying drawings, in which:

FIG. 1 is a longitudinal sectional view schematically illustrating an electric motor having an outer housing that enables liquid cooling according to an embodiment of the present invention. FIG. 2 is a longitudinal cross-sectional view schematically illustrating the same electric motor having the same outer housing that enables gas cooling according to another embodiment of the present invention.

  FIG. 1 is a longitudinal sectional view schematically showing an embodiment of an electric device such as a motor having an outer housing that enables liquid cooling according to the present invention.

  Basically, the electric motor 10 comprises a rotatable shaft 12, part of which forms a rotor 14 having at least a magnetic part surrounded by a stator 16. The rotatable shaft is supported at both ends by bearings 18A and 18B such as a rolling bearing and a magnetic bearing as illustrated. The stator is disposed in the outer housing 20 of the motor and includes a laminated magnetic stack 16A. The laminated magnetic stack 16A is surrounded by the winding 16B and disposed along the outer periphery of the rotor. An annular gap is formed between them. In particular, the laminated magnetic stack is in contact with the central portion of the outer housing 20, and the outer housing 20 also extends on both sides so as to surround other components of the motor. Furthermore, the transverse walls 22A, 22B close the outer housing on both sides of the rotatable shaft and also form an internal support for the bearing.

  In accordance with the present invention, the outer housing 20 has an inner surface 20A configured to couple at its central portion with the laminated magnetic stack 16A of the electric motor, the outer housing 20 being constant at the central portion. The outer surface 20 </ b> B has a plurality of cooling fins 24 that are not. In particular, the plurality of cooling fins have alternately high and low heights, all of the high cooling fins have the same height, and all of the low cooling fins have the same height. The cover plate 26 is fixed to the outer housing 20 by fixing means 28 such as bolts and screws, and a seal 30 is fitted between the cover plate and the outer housing to isolate liquid cooling.

  By being placed on the higher cooling fins, the cover plate allows the cooling passages between the higher and lower cooling fins (as illustrated by the arrows) to move liquid from the inlet manifold (not shown). The cover plate is completely penetrated and created from the inlet hole 26A (accepting cooling) to the outlet hole 26B (delivering liquid cooling to an outlet manifold not shown). In order to create such a cooling passage, the alternating higher and lower cooling fins are reversed on the inlet and outlet manifold sides.

  The outer housing with cooling fins is preferably realized by sand casting (internal cooling system means no leakage and surface roughness is compatible with heat exchange).

  The operation of the electric motor is well known and will not be described in detail. Classically, during operation, the rotor 14 rotates with the rotatable shaft 12 in the stator 16 such that an annular air gap is maintained between the two components to form part of a closed flux path. doing. The winding excitation current tends to create a magnetic force to generate a magnetic flux, attracting the rotor 14 toward the stator 16, thereby encouraging the rotor to produce a working torque output, in accordance with well-known magnetic principles. is there.

  Cooling takes place during operation of the motor. The inlet manifold carries a fluid cooling stream from a fluid injection pipe (not shown) through inlet hole 26A into the outer housing. This flow of fluid cooling circulates around the electric motor and exits through outlet hole 26B in the outlet manifold.

  FIG. 2 shows another embodiment of an electric motor having an outer housing according to the present invention that allows gas cooling.

  The various components of the electric motor are the same and will not be described again. These are of course given the same reference numbers. The same applies to the outer housing (inlet and outlet) for gas or liquid cooling. The only difference relates to the unique manifold for gas cooling and liquid cooling. In particular, the liquid cooling system cover plate 26 is not present in the gas cooling system and the outer housing is directly connected to the inlet and outlet manifolds 32. As shown, the inlet manifold carries a gas cooling flow from a blower (example but not shown) to the outer housing, which circulates the motor and exits the outlet manifold. This structure provides a leak-free mechanical connection between the gas blower and the motor housing, such as that realized between the liquid injection pipe and the housing in a liquid cooling system.

  The present invention allows a common design for various levels of power electric motors (no need to redesign the outer housing except for the two manifolds of the cooling system). With such a versatile configuration, the cooling medium (air or water) can be easily changed, and thereby the reachable power of the motor can be easily changed.

  While the preferred embodiment has been shown and described, it should be understood that any changes and modifications can be made without departing from the scope of the invention. In particular, if the present invention is described through an electric motor, other electrical devices (including generators, starters, alternators, etc.) having a stator stack coupled with a versatile housing are contemplated.

DESCRIPTION OF SYMBOLS 10 Electric motor 12 Rotatable shaft 14 Rotor 16 Stator 16A Laminated magnetic stack 16B Winding 18A, 18B Bearing 20 Outer housing 20A Inner surface 20B Outer surface 22A, 22B Transverse wall 24 Cooling fin 26 Cover plate 26A Inlet hole 26B Outlet hole 28 Fixing means

Claims (9)

  A housing (20) for an electrical device, an inner surface (20A) configured to be coupled with a laminated magnetic stack (16A) of the electrical device at a central portion, and a plurality of cooling fins (24 ) With an outer surface (20B), wherein the plurality of cooling fins are alternately higher and lower on the inlet manifold, and vice versa on the outlet manifold. All of the higher cooling fins have the same height to support the cover plate (26), the inlet hole (26A) receiving liquid cooling from the inlet manifold. And an outlet hole (26B) for delivering liquid cooling to the outlet manifold, wherein the cover plate has higher cooling fins and Ri low liquid cooling passages between the cooling fins to produce from said inlet port to said outlet hole, rests on a higher cooling fins than the housing.   The cover plate is secured to the housing by fastening means (28), and a seal is fitted between the cover plate and the housing to isolate liquid cooling. Housing.   The housing according to claim 2, wherein the cooling fin is realized by sand casting such that the surface roughness of the outer surface is adapted to heat exchange.   The housing according to claim 2 or 3, wherein all of the small cooling fins have the same height.   An electric device having a housing (20) having a plurality of cooling fins and a laminated magnetic stack (16A), wherein the plurality of cooling fins are located in a central portion along an outer surface (20B) of the housing Wherein the laminated magnetic stack is disposed in the housing and coupled to the inner surface (20A) of the housing at the central portion, wherein the plurality of cooling fins are higher at the inlet manifold Alternating ones and lower ones, and opposite the outlet manifold, with all of the higher cooling fins at the same height to support the cover plate (26) The cover plate includes an inlet hole (26A) for receiving liquid cooling from the inlet manifold, and liquid cooling for the outlet manifold. An outlet hole (26B) for delivery to a mold, wherein the cover plate creates a liquid cooling passage between the higher and lower cooling fins from the inlet hole to the outlet hole. An electrical device resting on a higher cooling fin.   6. The cover plate according to claim 5, wherein the cover plate is fixed to the housing by means of fixing means (28), and a seal is fitted between the cover plate and the housing to isolate liquid cooling. Electrical equipment.   The electrical device according to claim 6, wherein the cooling fin is realized by sand casting such that a surface roughness of the outer surface is adapted to heat exchange.   The electrical device according to claim 6 or 7, wherein all of the small cooling fins have the same height.   The electrical device of claim 5, comprising one of a motor, a generator, a starter, and an alternator.

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